Pulse tube cryocooler with axially-aligned components

What is claimed is: 1. A cryocooler comprising: a pulse tube; a regenerator; and a compressor; wherein the compressor includes a compressor piston axially-aligned with the pulse tube, wherein movement of the piston pushes a working fluid through the regenerator and the pulse tube; and wherein the compressor piston is annular piston having a central hole therethrough. 2. The cryocooler of claim 1 , further comprising a straight inertance tube segment, connected to the pulse tube and passing through the central hole, whereby the straight inertance tube segment is axially aligned with the compressor piston and the pulse tube. 3. The cryocooler of claim 2 , further comprising a coil of tubing attached to an end of the straight inertance tube segment that is opposite the pulse tube. 4. The cryocooler of claim 1 , further comprising a balancer that is operatively coupled to the compressor piston to move in an opposite direction from the compressor piston, to balance forces produced by movement of the compressor piston. 5. The cryocooler of claim 4 , wherein the balancer is actively controlled. 6. The cryocooler of claim 4 , wherein the balancer is axially aligned with the compressor piston and the pulse tube. 7. The cryocooler of claim 6 , further comprising an inertance tube, connected to the pulse tube and passing through a central hole of the balancer. 8. The cryocooler of claim 4 , wherein at least part of the balancer is radially within the compressor piston. 9. The cryocooler of claim 4 , further comprising balancer flexure stacks mechanically connected to the balancer and a housing of the cryocooler. 10. The cryocooler of claim 9 , wherein the balancer flexure stacks include non-rotating balancer flexures. 11. The cryocooler of claim 1 , further comprising compressor flexure stacks mechanically connected to the compressor and a housing of the cryocooler. 12. The cryocooler of claim 11 , wherein the compressor flexure stacks include non-rotating compressor flexures. 13. A cryocooler comprising: a pulse tube; a regenerator; and a compressor; wherein the compressor includes a compressor piston axially-aligned with the pulse tube, wherein movement of the piston pushes a working fluid through the regenerator and the pulse tube; further comprising a balancer that is operatively coupled to the compressor piston to move in an opposite direction from the compressor piston, to balance forces produced by movement of the compressor piston; wherein the balancer is actively controlled; and wherein the balancer is operatively coupled to an actuator to move the balancer axially. 14. The cryocooler of claim 13 , further comprising a controller operatively coupled to the actuator, to control movement of the balancer through control of the actuator. 15. The cryocooler of claim 14 , further comprising a vibration sensor operatively coupled to the controller. 16. A method of operating the cryocooler of claim 1 , the method comprising: moving the compressor piston of the cryocooler by oscillating the compressor piston along an axis of the compressor piston that is co-axial with the pulse tube of the cryocooler; and compensating for movement of the compressor piston by oscillation of the balancer that is co-axial with the compressor piston and the pulse tube, along the axis; wherein the compensating includes adjusting movement of the balancer using feedback from a vibration sensor that senses vibration of the cryocooler, to actively control the balancer. 17. A method of operating a cryocooler, the method comprising: moving a compressor piston of the cryocooler by oscillating the compressor piston along an axis of the compressor piston that is co-axial with a pulse tube of the cryocooler; and compensating for movement of the compressor piston by oscillation of a balancer that is co-axial with the compressor piston and the pulse tube, along the axis; wherein the compensating includes adjusting movement of the balancer using feedback from a vibration sensor that senses vibration of the cryocooler, to actively control the balancer; and wherein the adjusting movement of the balancer includes perturbing, based on the feedback, a signal sent to a balancer actuator that drives the balancer.